JPH01106680A - Adaptive adjustment of running time of video signal and audio signal to reference signal - Google Patents

Abstract

PURPOSE: To guarantee lip synchronization between a video signal and an audio signal by inserting a digitized audio signal into the horizontal blanking period of a video signal, storing the inserted signal, reading out the stored signal, and then separating both the signals again. CONSTITUTION: An analog video signal asynchronous with a studio reference signal from a terminal 2 is inputted to a terminal 1. The video signal is inputted to an audio/video synchronizing device 5 through an A/D converter 3. The input signal is converted into a digital video signal synchronized with the studio reference signal and the digital video signal is converted into an analog video signal again through a D/A converter 7 and outputted from a terminal 8. With this constitution, an audio signal is inputted to the device 5 through a terminal 9 and an A/D converter 10. The input signal is inserted into the horizontal blanking period area of the video signal and processed simultaneously with the video signal. Then the audio signal is separated from the video signal and outputted from a terminal 14 as an analog audio signal through a D/A converter 13. Consequently lip synchronization between the video signal and the audio signal is guaranteed.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The invention relates to a method for adapting the transit times of video and audio signals to a reference signal.

Conventional technology” Fernseh-and Kino-Techni
A method is known from pages 175 to 177 of "K" magazine, No. 5, 1981, for adapting an external video signal arbitrarily to the synchronization plane of a television studio.

In this known method, a video signal which is asynchronous to the television studio is A/D converted and written into a digital field memory using clock pulses derived from this asynchronous video signal. This digital field memory is read by clock pulses derived from the video reference signal. In the case of a video signal encoded in the PAII method and the use of a field memory, the maximum value of the transit time difference between the input signal and the output signal of the field memory is 20 mB. When using frame memory,
An even larger delay time (40ms') occurs.

Adaptation of transit time In order to guarantee lip-synchronization between the adjusted video signal and the audio signal accompanying this video signal, the audio signal is usually adapted to the delay time of the video signal in a so-called digital audio synchronization device. be adjusted. This type of audio synchronization device includes a digital memory as a controllable delay element. Depending on the transit time difference between the two video signals, the audio signal is delayed accordingly.

Problem to be Solved by the Invention The object of the invention is therefore to provide a method as mentioned at the outset, which guarantees ridge synchronization between video and audio signals and at the same time reduces costs.

Advantages of the Invention The method according to the invention having the features indicated in the characterizing part of claim 1 has the advantage that audio memory for delaying the audio signal accompanying the video signal is saved. This also eliminates the need for expensive circuitry for audio memory control. For example, in the method according to the present invention, when a plurality of video synchronization devices are connected in series,
This has the advantage that the audio signal accompanying the video signal is precisely adjusted to the running time of the video signal. This type of series connection can be used in large television transmission line networks.
For example, this is commonly used in satellite relay sections.

The embodiments of the method according to claim 1 are possible with the configurations described in claims 2 and below. For example, using analog multiplexing techniques or digital multiplexing techniques, multiple audio signals, e.g. This has the advantage of further saving.

DESCRIPTION OF THE PREFERRED EMBODIMENTS An illustrative embodiment of the method according to the invention is shown in the drawing. In FIG. 1, audio
A schematic block diagram of a video synchronization device is shown. At terminal 1, an analog video signal is applied which is asynchronous to the studio reference signal at terminal 2. This analog video signal is A/D converted by an A/D converter 3 (input side 4 of an audio/video synchronizer 50).
be led to. The word length of the digital video signal is n bits. A digital video signal synchronized with the studio reference signal is then transferred from the output side 6 of the audio/video synchronization device 5 to a D/A converter 7 and subjected to D/A conversion.

At the terminal 8, an analog video signal can be taken out again.

A/D converters 3 and D provided in the video signal path
The /A converters T are advantageously combined into one interface arrangement to limit crosstalk to the parallel audio signal paths. Similarly, the A/D converter 10 and the D/A converter 13 are combined into a single interface component to avoid crosstalk. The components of this interface are shown in dashed lines. The video signal path described so far corresponds substantially to the video signal path of known video synchronization devices according to the prior art. However, the image memory in known video synchronization devices is used only for video signals.

According to the method of the invention, the image memory K is also used in the invention for the transit time adaptation adjustment of the audio signal accompanying the video signal. For this purpose, the audio signal present at terminal 9 is conducted via an A/D converter 10 to an input 11 of audio-video synchronization device 5.

A/The digital audio signal is added to the digital video signal, processed simultaneously with the video signal, and then separated from the video signal again. A digital audio signal whose travel time is adjusted to match the video signal.
From the output 12 of the audio/video synchronizer 5 to D/
A converter 13 is reached. The D/A converted analog audio signal can be taken out at the terminal 14.

The block diagram of FIG. 2 shows the schematic block diagram of FIG. 1 in greater detail. Zolotskus that have the same effect have the same reference symbol.

Via terminal 1, a video signal asynchronous to the studio reference signal is led to an A/D converter 3. A/D converter 3
For example, from the output side of a PC with a word length of 8 bits! An M (pulse code modulation) video signal is taken. The audio signal applied to terminal 9 is converted by A/D converter 10 into a POM audio signal having a word length of, for example, 16 bits. That is, the word length of the audio signal is A/D
For the conversion process or D/A conversion process, the length is chosen to be twice the word length of the video signal.

The asynchronous video signal applied to terminal 1 is further transferred to control unit 15. In this control unit 15, various clock pulse signals and control signals are formed which are combined with the horizontal synchronization signal of the asynchronous video signal and/or with the studio reference signal. This coupling takes place, for example, in a phase control loop (oscillator lock), which is known per se. In this case, the oscillator of this phase control loop is controlled to follow the frequency i 3.5 MHz. Individual clock pulse signals and control signals are derived from the oscillator signal by branching and pulse shaping. For the writing process, this control unit 15 provides a clock pulse signal with a frequency of 13.5 MHz and an A/D converter 3 for time-selectively sampling the video signal.
D converter 1 i1 Derives a clock pulse signal with a frequency of 48 KH2 for time-selectively sampling the crab audio signal, a clock pulse signal with a frequency of 6.75 MHz, and a blanking signal with a horizontal frequency.

The digital audio signal taken out from the output side of the A/D converter 10 is led to the input side of a compression memory xs15, which is made up of, for example, an FO (first in, first out).

This digital audio signal is read into the FO using a 48KHz clock pulse signal, and the 6.75M
It is read out again using a Hz clock pulse signal and transferred to the shift register 17. This audio signal is shifted in the shift register 17 by a clock pulse signal of 13.5 M)Iz. At this time, the word length is converted from 16 bits to 8 bits. That is,
The word length of the audio signal is adjusted to match the word length of the video signal before the digital signal processing process. The audio signal processed in this way is passed to the input 18 of the multiplexer 19. The other input side 2 of multiplexer 19
A digital video signal is added to 0. Control of multiplexer 19 is effected by horizontal frequency blanking signal AH. The output side of multiplexer 19 is connected to the input side of memory 21 . In this memory, the combined video/audio signal is read under the address control of the address generator 22. Throughout the read process, address signals are derived from the asynchronous EDIO signals. Memory 21 is read using the address signal of address generator 22, which is derived from the reference signal at terminal 2. The output side of the memory 21 is connected to the input terminal 23 of the demultiplexer 24 . In the demultiplexer 24, the video signal component and the audio signal component are again separated by control using a horizontal frequency blanking signal derived from the reference signal.

Both components are converted back into an analog video signal and an analog audio signal in the opposite direction to the processing on the input side. For this purpose, in the control unit 15, terminal 2
Further control and clock pulse signals are derived that are combined with the reference signal of. The control unit 15 is a D/A
Converter 7. and the frequency 1 of the shift register 25
A clock pulse signal of 6.5 MHz and an extension note for the D/A converter 13 and also configurable by the FO! j D S 26 clock pulse signal with a frequency of 48 KHz, as well as the demultiplexer 24
Nodame horizontal frequency blanking coefficient is formed. In the shift register 25, the word length of the audio signal component present at the output 27 of the demultiplexer 24 is converted from 8 bits to 16 bits. This results in a correspondingly wired shift register 25 with a frequency of 13.
This is done using a 5 MHz clock pulse signal. The output side of the shift register 25 is connected to the input side of the expansion memory 26.

The digital audio signal stored in this expansion memory is read in with a clock pulse signal of 6.75 MHz frequency and read out with a clock pulse signal of 48 KHz frequency. The obtained audio signal bits having a word length of 16 bits are converted into an analog audio signal by the D/A converter 13, and this signal is taken out from the terminal 14. The digital video signal component present at the output 27 of the demultiplexer 24 is directly converted back to an analog video signal by a D/A converter 7. This analog video signal is output from a terminal 8 on the output side of the /A converter 7.

Since the audio signal is transmitted during the horizontal blanking period of the video signal, the audio signal is delayed by the same amount of time as the video signal to which it belongs. Additional memory costs for lip-syncing and adjusting the transit time of the audio signal to the video signal are no longer required.

A plurality of audio signals, for example a stereo signal, are A/
Before A/D conversion in the Ty converter 10, the signals are combined using a frequency division multiplexing method or a time division multiplexing method. That is, the method of the present invention provides that the multisolex processing and demultiplexing of an audio signal is performed under a frequency selective operation, or the multisolex processing and demultiplexing of an audio signal is performed under a time selective operation. Multiple audio signals can also be transmitted in ridge-sync format with respect to video signals. An arrangement for transmitting an audio signal in the region of the horizontal blanking interval of a video signal is known, for example, from DE 31 09 091. However, this known technique is only concerned with limiting the frequency range required for the transmission of audio signals.

The voltage-time diagram shown in FIG. 3 is used for a detailed explanation of the signal processing on the input side of the audio signal. FIG. 3a shows, as an example, the least significant bit LS of the digital audio signal at the output side of the A/D converter 10.
B, in whose A/D converter an analog audio signal is time-selectively sampled at a frequency of 48 KH2. The order of digital words is An,
Bn.

On, etc., in which case AO is the least significant bit of the first word, Bo is the least significant bit of the second word, etc. ing. For example, A8 represents the 9th bit of the first word and B8 represents the 9th bit of the second word. In the compression memory 16 the individual words, which are defined by various read and write clock controls, are compressed in time. FIG. 3 shows the temporal variation of the least significant bit at the output side of the compression memory 16-. During the word length conversion from 16 bits to 8 bits, bits Ao and B8) are transmitted in one word period, correspondingly both bits Bo and B8 in the following word period, and so on. transmitted to. In FIG. 3C, the process of converting the least significant word at the output of the decompression memory 26 is shown. FIG. 6d shows the blanking period of the horizontal frequency blanking signal applied to the control signal input of multiplexer 19. FIG. During this blanking period, a digital audio burst (FIG. 3C) is inserted into the digital video signal.

Since audio signal processing on the output side is performed in the opposite direction, further explanation can be omitted.

The method of the invention is not limited to the audio signal processing circuit shown in the Zorock diagram. Other methods for inserting the audio signal into the blanking period of the video signal are also possible.

Effects of the Invention According to the present invention, ridge synchronization between the kedeo signal and the audio signal is guaranteed, and even when a plurality of video synchronization devices are connected in series, the running time of the audio signal and the kedeo signal can be accurately matched. A method is provided in which the audio memory for delaying the audio signal that accompanies the video signal is saved.

[Brief explanation of the drawing]

FIG. 1 shows a simple block diagram for explaining the method according to the invention, and FIG. 2 shows a detailed Zorok diagram,
Further, FIG. 3 is a voltage and time diagram for explaining the block diagram shown in FIG. 2 in more detail. 1... Input terminal for analog video signal, 2... Input terminal for studio reference signal, 3... A/D converter, 4...
...Input end of audio/video synchronization device, 5...
Audio/video synchronization device, 6...Output side of audio/video synchronization device, 7...D/A
Converter, 8... Analog video signal output terminal, 9.
...Analog audio signal input terminal, 10...A
/ D converter, 11... Input side of audio/video synchronization device, 12... Output side of audio/video synchronization device, 13... D/'A converter, 14... Analog audio Signal output terminal, 15... Control unit, 16... Compression memory, 17... Shift register, 1B... Input side of multiplexer, 19... Multiplexer, 20... Input side of multiplexer ,
21...Memory, 22...Address generator, 23.
...Input side of the demultiplexer, 24...Demultiplexer, 25...Shift register, 26...Expansion memory, 2γ...Output side of the demultiplexer - (J)

Claims (1)

[Claims] 1. A method for adapting the transit times of video and audio signals to a reference signal, in which the video and audio signals are written in digital form to a memory and further dependent on this writing process. In the transit time adaptation adjustment method, the audio signal is inserted into the blanking interval of the video signal before writing to a memory (21), and further the audio signal is 21), the inserted audio signal is again separated from the video signal. 2. The audio signal is time-selectively sampled and pulse code modulated, and the resulting digital audio signal is temporally compressed and inserted in the horizontal blanking period region of the video signal. The method according to claim 1. 3. Before writing multiple audio signals assigned to one video signal to one memory (21), multiplex processing is used to combine them into one overall audio signal, and furthermore, the one memory (21) 2. The method as claimed in claim 1, further comprising converting the overall audio signal separated from the video signal after being read out from the video signal into individual audio signals by demultiplexing. 4. A/D convert the video signal and audio signal, and
/D converted audio signal is written to the compression memory (16) using the first clock pulse signal,
Furthermore, the second clock pulse signal is used to read out from the compression memory (16), and further the compression memory (16) is read out using the second clock pulse signal.
6) is added to the A/D converted video signal in a time division multiplexed format during the horizontal blanking period, and the resulting digital signal is processed in the memory (21). Furthermore, the signal read out from the memory (21) is separated into a video signal component and an audio signal whose running times have been suitably adjusted by demultiplexing, and the audio signal component is separated by a third clock pulse signal. A fourth clock pulse signal is used to write to the decompression memory (26), and a fourth clock pulse signal is used to read from the decompression memory (26), and the resulting transit time adaptation adjusted digital video signal and transit time adaptation 3. The method according to claim 1, wherein the adjusted digital audio signal is subjected to D/A conversion. 5. If the audio signal has a longer word length than the video signal,
5. The method according to claim 4, wherein D conversion or D/A conversion is performed. 6. The word length of the word in the signal sent out from the compression memory (16) is halved in the first device (17) for word length variation using the fifth clock pulse; , the word length of the word in the signal sent out from the demultiplexer (24) is doubled in the second device (26) for word length variation using the sixth clock pulse signal. 4. The method described in 4 or 5.